In a battery pack structure for electric vehicles that a battery module, a junction box, and a battery controller for battery management are mounted in a battery-pack-case internal space, clearances, ensured when the battery module is mounted in the case internal space, are configured as temperature-adjustment air passages through which temperature-adjusting air flows. The junction box and the battery controller are arranged at positions spaced apart from each other and facing one straight passage part of the temperature-adjustment air passages. Furthermore, a weak-electric harness, via which the junction box and the battery controller are connected to each other, is wired along the straight passage part, thus ensuring smooth flow of temperature-adjusting air, while improving both the harness-wiring workability and the harness durability.
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1. A battery pack structure for use in an electric vehicle, comprising:
a plurality of battery modules mounted in an internal space of a battery pack case, and structured to define a plurality of clearances as temperature-adjustment air passages,
a junction box mounted in the internal space of the battery pack case and configured to perform supply, interception, and distribution of heavy-electric current by a relay circuit, and
a battery controller mounted in the internal space of the battery pack case for battery management,
wherein the junction box and the battery controller are arranged at positions spaced apart from each other in a vehicle fore-and-aft direction such that the junction box faces a frontmost end of one straight passage part of the temperature-adjustment air passages and that the battery controller faces a rearmost end of the one straight passage part,
wherein a harness via which the junction box and the battery controller are connected to each other, is wired along and located within the one straight passage part,
wherein the internal space of the battery pack case is partitioned into two regions in the vehicle fore-and-aft direction to define a battery module mounting region on a first side of the battery pack case and an electrical equipment mounting region on a second side of the battery pack case, the second side being opposite to the first side in the vehicle fore-and-aft direction,
wherein the battery module mounting region is split into at least two split regions to define a first battery module mounting region mounting a first battery module and a second battery module mounting region mounting a second battery module different from the first battery module, the first battery module mounting region being disposed at a rear end of the battery pack case and the second battery module mounting region being interposed between the first battery module mounting region and the electrical equipment mounting region, and
wherein the battery controller is arranged in the first battery module mounting region, while the junction box is arranged in the electrical equipment mounting region separated from the first battery module mounting region in the vehicle fore-and-aft direction by the second battery module mounting region.
2. A battery pack structure for use in an electric vehicle, comprising:
a plurality of battery modules mounted in an internal space of a battery pack case, and structured to define a plurality of clearances as temperature-adjustment air passages,
a junction box mounted in the internal space of the battery pack case and configured to perform supply, interception, and distribution of heavy-electric current by a relay circuit, and
a battery controller mounted in the internal space of the battery pack case for battery management,
wherein the junction box and the battery controller are arranged at positions spaced apart from each other such that the junction box faces one end of one straight passage part of the temperature-adjustment air passages and that the battery controller faces another end of the one straight passage part,
wherein a harness via which the junction box and the battery controller are connected to each other, is wired along and located within the one straight passage part,
wherein the internal space of the battery pack case is partitioned into two regions in a vehicle fore-and-aft direction to define a battery module mounting region on a first side of the battery pack case and an electrical equipment mounting region on a second side of the battery pack case, the second side being opposite to the first side in the vehicle fore-and-aft direction,
wherein the battery module mounting region is split into at least two split regions to define a first battery module mounting region at one end of the battery pack case and a second battery module mounting region interposed between the first battery module mounting region and the electrical equipment mounting region,
wherein the battery controller is arranged in the first battery module mounting region, while the junction box is arranged in the electrical equipment mounting region,
wherein the battery module mounting region is classified into a plurality of split rectangular regions configured to mount the plurality of battery modules, respectively, and
wherein the battery controller is arranged upright in a first split rectangular region of the plurality of split rectangular regions, the first split rectangular region corresponding to the first battery module mounting region and configured to mount one battery module of the plurality of battery modules, the one battery module being constructed by battery cells upright-stacked in a vehicle width direction.
4. A battery pack structure for use in an electric vehicle, comprising:
a plurality of battery modules mounted in an internal space of a battery pack case and structured to have temperature-adjustment air passages,
a junction box mounted in the internal space of the battery pack case and configured to perform supply, interception, and distribution of heavy-electric current by a relay circuit, and
a battery controller mounted in the internal space of the battery pack case for battery management,
wherein the junction box and the battery controller are arranged at positions spaced apart from each other such that the junction box faces one end of one straight passage part of the temperature-adjustment air passages and that the battery controller faces another end of the one straight passage part,
wherein a harness via which the junction box and the battery controller are connected to each other, is wired along and located within the one straight passage part,
wherein the internal space of the battery pack case is partitioned into two regions in a vehicle fore-and-aft direction to define a battery module mounting region on a first side of the battery pack case and an electrical equipment mounting region on a second side of the battery pack case, the second side being opposite to the first side in the vehicle fore-and-aft direction,
wherein the battery module mounting region is split into at least two split regions to define a first battery module mounting region at one end of the battery pack case and a second battery module mounting region interposed between the first battery module mounting region and the electrical equipment mounting region, and
wherein the battery controller is arranged on a first side end of the first battery module mounting region, facing the one straight passage part disposed between the battery controller and one side of both sides of the battery pack case in a vehicle width direction, while the junction box is arranged on a first side end of the electrical equipment mounting region, facing the one straight passage part disposed between the junction box and the one side of the battery pack case in the vehicle width direction,
wherein the battery module mounting region is classified into a plurality of split rectangular regions configured to mount the plurality of battery modules, respectively, and the battery controller is arranged upright in a first split rectangular region of the plurality of split rectangular regions, the first split rectangular region corresponding to the first battery module mounting region and configured to mount one battery module of the plurality of battery modules, the one battery module being constructed by battery cells upright-stacked in a vehicle width direction.
3. The battery pack structure as recited in
the temperature-adjustment air passages are configured to have a loop passage for returning temperature-adjusting air, heat-exchanged with each of the plurality of battery modules and then flown into a circumference of the case internal space, and
the one straight passage part is configured as a passage constructing a part of the loop passage and formed along one side of both sides of the battery pack case in the vehicle width direction.
5. The battery pack structure as recited in
the temperature-adjustment air passages are configured to have a loop passage for returning temperature-adjusting air, heat-exchanged with each of the plurality of battery modules and then flown into a circumference of the case internal space, and the one straight passage part is configured as a passage constructing a part of the loop passage.
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The present invention relates to a battery pack structure in which a battery module, a junction box, and a battery controller are mounted in the internal space of a battery pack case.
In a battery pack for electric vehicles, a battery module constructed by a battery cell assembly, a junction box for performing supply, interception, and distribution of heavy-electric current by means of a relay circuit, and a battery controller for battery management are mounted in the internal space of a battery pack case. In such a battery pack, a battery pack structure, in which a battery module, a junction box, and a battery controller are connected to each other by means of a heavy-electric harness constructed by heavy-electric wires tied together and a weak-electric harness constructed by weak-electric wires tied together, is well known. One such battery pack structure has been disclosed in Patent document 1.
However, in the battery pack structure disclosed in Patent document 1, the internal space of the battery pack case is classified into three-split rectangular regions, and three battery modules are mounted on the respective rectangular regions. Also, a T-shaped clearance space, defined among sidewalls of the three battery modules, opposed to each other, is used as a junction-box mounting space and also used as a harness wiring path. Therefore, when connecting the junction box and the battery controller, mounted apart from each other, to each other via a harness, harness-wiring that the harness has to be bent along the bent clearance path is required. This leads to the problem, such as the deteriorated workability of the harness wiring and the lowered durability of the harness.
On the other hand, the clearances, ensured when the plurality of battery modules have been mounted in the internal space of the battery pack case, are also used as temperature-adjustment air passages through which temperature-adjusting air for battery-temperature management flows. In this manner, the clearances, ensured when the plurality of battery modules have been mounted, serve as the temperature-adjustment air passages and also serve as the harness wiring paths. Hence, the bent harness, which may disturb the temperature-adjusting air flow, has to be wired in the clearances through which the temperature-adjusting air flows. As a result of this, there is a problem that such a bent harness acts as passage resistance and thus smooth flow of temperature-adjusting air cannot be ensured.
Patent document 1: PCT International Publication No. WO2010/098271 (Al)
It is, therefore, in view of the previously-described drawbacks of the prior art, an object of the invention to provide a battery pack structure for electric vehicles in which smooth flow of temperature-adjusting air can be ensured, while improving the harness-wiring workability and the harness durability in the harness connection of a junction box and a battery controller.
In order to accomplish the aforementioned and other objects, the battery pack structure for electric vehicles of the present invention is based on the assumption that a battery module constructed by a battery cell assembly, a junction box for performing supply, interception, and distribution of heavy-electric current by means of a relay circuit, and a battery controller for battery management are mounted in the internal space of a battery pack case. In the battery pack structure for electric vehicles, clearances, ensured when the battery module is mounted in the internal space of the battery pack case, are configured as temperature-adjustment air passages through which temperature-adjusting air flows. Also, the junction box and the battery controller are arranged at positions spaced apart from each other and facing one straight passage part of the temperature-adjustment air passages. Furthermore, a harness via which the junction box and the battery controller are connected to each other, is wired along the straight passage part.
Hence, the junction box and the battery controller are arranged at the positions spaced apart from each other and facing the one straight passage part of the temperature-adjustment air passages defined in the internal space of the battery pack case, and also connected to each other via the harness wired along the straight passage part.
Therefore, when connecting the junction box and the battery controller to each other via the harness, only the work of simplified harness-wiring (simplified harness-routing) along the one straight passage part is required. For the reasons discussed above, it is possible to improve both the harness-wiring workability and the harness durability, as compared to the harness wiring in the bent path.
Furthermore, the harness, wired along the one straight passage part of the temperature-adjustment air passages, is configured as a straight harness extending straight along the flow of temperature-adjusting air flowing through the straight passage part. Thus, it is possible to suppress the passage resistance low, as compared to the bent-harness routing which may disturb the temperature-adjusting air flow. Hence, it is possible to ensure smooth flow of temperature-adjusting air.
As a result of this, when connecting the junction box and the battery controller to each other via the harness, it is possible to ensure smooth flow of temperature-adjusting air, while improving both the harness-wiring workability and the harness durability.
Preferred embodiments that realize a battery pack structure for electric vehicles, made according to the invention, are hereinafter described in detail in reference to the first embodiment shown in the drawings.
First, the constructions/configurations of the battery pack structure for electric vehicles in the first embodiment are divided into “MOUNTING CONSTRUCTION OF BATTERY PACK BP”, “PACK COMPONENTS OF BATTERY PACK BP”, “REGION-PARTITIONING CONFIGURATION FOR CASE INTERNAL SPACE OF BATTERY PACK BP”, “CONFIGURATION OF BUS-BAR CONNECTION OF BATTERY HEAVY-ELECTRIC CIRCUIT”, and “CONFIGURATION OF HARNESS-CONNECTION AMONG PACK COMPONENTS”, and explained every divided constructions/configurations.
[Mounting Construction of Battery Pack BP]
Referring to
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As shown in
Returning to
Battery pack BP is connected to an air-conditioning system employing the air-conditioning unit 107 located in the instrument panel 105. That is to say, an internal temperature in the battery pack BP, in which battery modules (described later) are mounted, is managed or controlled by temperature-adjusting air (cold air and/or hot air). By the way, cold air is created by introducing refrigerant from the air-conditioning system by way of a branch refrigerant pipe. On the other hand, hot air is created by operating a PTC (positive temperature coefficient) heater incorporated in the air-conditioning system via a PTC harness.
Battery pack BP is connected to an external electronic control system via a bidirectional communication line such as a CAN (controller area network) cable. That is to say, regarding the battery pack BP, discharging control (power-running control) and/or charging control (quick-charging control, normal-charging control, regenerative control, and the like) of each of the battery modules is carried out by unified control based on information exchange with the external electronic control system.
[Pack Components of Battery Pack BP]
Referring to
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[Region-Partitioning Configuration for Case Internal Space of Battery Pack BP]
As shown in
Battery module mounting region 7 is classified into three-split rectangular regions, namely, a first split rectangular region 71, a second split rectangular region 72, and a third split rectangular region 73, by a T-shaped passage (a central passage 36 and an intersecting passage 37). The first battery module 21, which has the LB controller 6 attached to one side face, is mounted in the first split rectangular region 71. The second battery module 22 is mounted in the second split rectangular region 72. The third battery module 23 is mounted in the third split rectangular region 73.
Electrical equipment mounting region 8 is classified into three partitioned regions in the vehicle width direction, namely, a first partitioned region 81, a second partitioned region 82, and a third partitioned region 83. Temperature-adjustment air unit 3 is mounted within an area ranging from the first partitioned region 81 to the lower part of the second partitioned region 82. SD switch 4 is mounted in the upper part of the second partitioned region 82. Junction box 5 is mounted in the third partitioned region 83.
Temperature-adjustment air passages for internal circulation of temperature-adjusting air, created by temperature-adjustment air unit 3, are configured in the internal space of battery pack BP, utilizing the clearances ensured when battery modules 21, 22, and 23 have been mounted in the respective split rectangular regions. As the temperature-adjustment air passages, the central passage 36 through which temperature-adjusting air, blown off from the temperature-adjustment air unit 3, flows first, the intersecting passage 37 for distributing the flow from the central passage 36 to both sides in the vehicle width direction, and a loop passage 38 for returning the temperature-adjusting air flown into the circumference of the internal space to the temperature-adjustment air unit 3, are provided. Central passage 36 is configured by keeping or defining a clearance between two opposed faces of the second battery module 22 and the third battery module 23. Intersecting passage 37 is configured by keeping or defining a clearance defined between two opposed faces of the first battery module 21 and the second battery module 22 and between two opposed faces of the first battery module 21 and the third battery module 23. Loop passage 38 is configured by keeping or defining a clearance or a margin between the battery pack lower frame 11 and each pack component 2, 3, 4, 5, and 6.
In addition to the three major temperature-adjustment air passages through which temperature-adjusting air flow mainly, that is, the central passage 36, the intersecting passage 37, and the loop passage 38, apertures and clearance spaces defined by mounting the pack components 2, 3, 4, 5, and 6 in the case internal space are also included in the temperature-adjustment air passages. For instance, regarding the first battery module 21, an aperture that is defined between adjacent stacked battery cells, each used as a unit cell, and configured in the same direction as the flow direction of temperature-adjusting air, serves as a temperature-adjustment air passage. Regarding the second battery module 22 and the third battery module 23, a mounting interval defined between one set of 4 pieces of flat-stacked battery cell and one set of 5 pieces of flat-stacked battery cell, and a mounting interval defined between the one set of 5 pieces of flat-stacked battery cell and the other set of 5 pieces of flat-stacked battery cell serve as temperature-adjustment air passages. Regarding the electrical equipment mounting region 8, a clearance space defined between the inside of battery pack upper cover 12 and the outside faces of components such as temperature-adjustment air unit 3 and junction box 5 serves as a temperature-adjustment passage.
[Configuration of Bus-Bar Connection of Battery Heavy-Electric Circuit]
Referring to
As shown in
In the above-mentioned battery heavy-electric circuit, the term “internal bus bar” means an electrically conductive plate connected to terminals of a plurality of battery cells constructing each of battery modules 21, 22, and 23. On the other hand, the term “external bus bar 90” means an electrically conductive plate for connecting between terminals of the internal bus bars so as to form or configure a battery heavy-electric circuit (described later). The external bus bar is comprised of a first external bus bar 90a, a second external bus bar 90b, and a third external bus bar 90c. As shown in
In the above-mentioned battery heavy-electric circuit, the three-split battery modules 21, 22, and 23 are designed to provide a circuit configuration in which the total number of battery cells (48 pieces) is divided into two-divided battery-cell sets, each having 24 pieces. Junction box 5 and SD switch 4 are connected to each divided battery-cell set via respective bus bars. That is to say, on one hand, the first battery module 21 (20 pieces), the second battery module 22 (2 pieces), and the third battery module 23 (2 pieces) are combined into one battery-cell set (24 pieces in total). On the other hand, the second battery module 22 (14 pieces−2 pieces=12 pieces) and the third battery module 23 (14 pieces−2 pieces=12 pieces) are combined into the other battery-cell set (24 pieces in total).
[Configuration of Harness-Connection Among Pack Components]
Referring to
As the configuration of harness-connection among pack components of battery pack BP of the first embodiment, a weak-electric harness-connection configuration between junction box 5 and LB controller 6, a heavy-electric harness-connection configuration between battery module 2 and LB controller 6, and a weak-electric harness-connection configuration between battery module 2 and LB controller 6 are provided.
As shown in
Junction box 5 is arranged at the position corresponding to one end of the vehicle width direction of the electrical equipment mounting region 8 and facing the straight passage part 38a.
LB controller 6 is arranged upright at the position corresponding to one end of the vehicle width direction of the first split rectangular region 71, in which the first battery module 21 constructed by a plurality of battery cells upright-stacked in the vehicle width direction is mounted, and facing the straight passage part 38a.
As shown in
As shown in
Heavy-electric harness 97 is constructed by binding a first battery voltage detection line 97a, a second battery voltage detection line 97b, and a third battery voltage detection line 97c together. The first battery voltage detection line 97a is connected to a bus-bar end of the first external bus bar 90a in the vicinity of the LB controller 6. The second battery voltage detection line 97b and the third battery voltage detection line 97c are respectively connected to a bus-bar end of the second external bus bar 90b and a bus-bar end of the third external bus bar 90c in the vicinity of the intersecting passage 37.
As shown in
Battery voltage detection lines 97a, 97b, and 97c of heavy-electric harness 97 are designed to supply respective battery voltage values of battery modules 21, 22, and 23 to the LB controller 6. LB controller 6 is configured to acquire, based on the supplied battery voltage values, battery-voltage information, and also configured to acquire, based on a characteristic showing the relationship between battery capacities and battery voltage values, battery-capacity information. For instance, a lithium-ion battery has a characteristic that a battery capacity and a battery voltage value vary linearly each other.
As shown in
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The operations/actions, provided by the battery pack structure for electric vehicles in the first embodiment, are divided into “CHARGING/DISCHARGING OPERATION OF BATTERY PACK BP”, “INTERNAL TEMPERATURE MANAGEMENT/CONTROL ACTION OF BATTERY PACK BP”, “HARNESS-CONNECTION WORK AMONG PACK COMPONENTS”, and “HARNESS-CONNECTION WORK BETWEEN JUNCTION BOX AND LB CONTROLLER”, and explained every divided operations/actions.
[Charging/Discharging Operation of Battery Pack BP]
Battery pack BP, in which secondary batteries, such as lithium-ion batteries or the like, are mounted, is often compared to a fuel tank of a vehicle equipped with an engine. In the battery pack, a charge for increasing battery capacity and a discharge for decreasing battery capacity are repeated. The charging/discharging operation of battery pack BP is hereunder explained.
When quick-charging with the vehicle stopped at a quick-charging stand (a quick-charging station), first of all, a charging-port lid, located in the front end of the vehicle, is opened. Then, a quick-charging connector of the charging stand side is inserted into the quick-charging port 115 of the vehicle side. During quick-charging operation, a direct-current quick-charging voltage is supplied to the DC/DC converter of heavy-electric module 112 through the quick-charging harness 117, and then converted into a direct-current charging voltage by voltage-conversion of the DC/DC converter. The direct-current charging voltage is supplied via the charging/discharging harness 111 to the battery pack BP, and thus supplied to the battery cells of each of battery modules 21, 22, and 23 via the junction box 5 and the bus bars installed in the battery pack BP, for charging them.
When normal-charging with the vehicle parked at home, first of all, the charging-port lid, located in the front end of the vehicle, is opened. Then, a normal-charging connector of the home power-supply side is inserted into the normal-charging port 116 of the vehicle side. During normal-charging operation, an alternating-current normal-charging voltage is supplied to the charger of heavy-electric module 112 through the normal-charging harness 118, and then converted into a direct-current charging voltage by voltage-conversion and ac/dc conversion of the charger. The direct-current charging voltage is supplied via the charging/discharging harness 111 to the battery pack BP, and thus supplied to the battery cells of each of battery modules 21, 22, and 23 via the junction box 5 and the bus bars installed in the battery pack BP, for charging them.
During a power-running mode at which the vehicle is running by a driving force produced by the drive motor, a direct-current battery voltage from each of battery modules 21, 22, and 23 is discharged from the battery pack BP via the bus bars and the junction box 5. The discharged direct-current battery voltage is supplied to the DC/DC converter of heavy-electric module 112 via the charging/discharging harness 111, and then converted into a direct-current driving voltage by voltage-conversion of the DC/DC converter. The direct-current driving voltage is converted into an alternating-current driving voltage by dc/ac conversion of inverter 113. The alternating-current driving voltage is applied to the drive motor of motor drive unit 114, so as to rotate the drive motor.
With the drive motor put in regenerative operation during which the drive motor serves as a generator in the presence of a decelerating requirement, the drive motor carries out a power-generation function, for converting a rotational energy inputted from tires of drive road wheels into a generated energy. An alternating-current generated voltage, produced by the generated energy, is converted into a direct-current generated voltage by ac/dc conversion of inverter 113, and then converted into a direct-current charging voltage by voltage-conversion of the DC/DC converter of heavy-electric module 112. The direct-current charging voltage is supplied to the battery pack BP via the charging/discharging harness 111, and thus supplied to the battery cells of each of battery modules 21, 22, and 23 via the junction box 5 and the bus bars installed in the battery pack BP, for charging them.
[Internal Temperature Management/Control Action of Battery Pack BP]
The battery has a high temperature dependency, and thus the battery performance is different depending on whether the battery temperature is high or low. For the reasons discussed above, in order to maintain a high battery performance, it is necessary to manage or control the internal temperature (=battery temperature) of battery pack BP. The internal temperature management/control action of battery pack BP, reflecting the necessity discussed above, is hereunder explained in reference to
First, a temperature-adjustment control action, performed by means of temperature-adjustment controller 52, is discussed. For instance, when the internal temperature of battery pack BP exceeds a first set temperature due to continuous battery charging/discharging loads and/or high outside air temperatures, refrigerant is introduced into the evaporator 33 of temperature-adjustment air unit 3, and the blower fan 32 is rotated. Thereby, heat is removed from the air passing through the evaporator 33 and thus cold air is created. By circulation of the cold air in the case internal space, in which the first battery module 21, the second battery module 22, and the third battery module 23 are mounted, the internal temperature (=battery temperature) of battery pack BP can be reduced.
In contrast, when the internal temperature of battery pack BP becomes less than a second set temperature due to cold-air circulation and/or low outside air temperatures, the PTC heater of the temperature-adjustment air unit is energized, and the blower fan is rotated. Thereby, heat is added to the air passing through the PTC heater and thus hot air is created. By circulation of the warm air in the case internal space, in which the first battery module 21, the second battery module 22, and the third battery module 23 are mounted, the internal temperature (=battery temperature) of battery pack BP can be risen.
As discussed above, by performing temperature-adjustment control for battery pack BP, the internal temperature of battery pack BP can be maintained in a temperature range from the first set temperature to the second set temperature, within which a high battery performance can be ensured. At this time, it is important to circulate temperature-adjusting air equally smoothly throughout the case internal space without any space having a lack in the quantity of temperature-adjusting air circulation. This is because the internal temperature control of battery pack BP is aimed at maintaining the temperatures of first, second, and third battery modules 21, 22, and 23, which modules are mounted in the case internal space, in the battery temperature range that ensures a high battery performance. The operation of temperature-adjusting air in the case internal space is hereunder described.
As indicated by the arrow D in
The heat-exchange of the first battery module 21 is performed by heat-transfer with the temperature-adjusting air flows indicated by the arrows E, E in
The heat-exchange of the second battery module 22 and the heat-exchange of the third battery module 23 are performed by heat-transfer with the temperature-adjusting air flow indicated by the arrow D in
As discussed above, the air, which finished heat-exchange with each of first, second, and third battery modules 21, 22, and 23, flows into the loop passage 38 defined in the circumference of the internal space. As indicated by the arrows I, I in
Next, the operation that creates cold air or hot air from the heat-exchanged air, returned to the unit suction side, within the temperature-adjustment air unit 3, is hereunder explained. As indicated by the arrow in
As discussed above, the first embodiment adopts a specified layout/configuration that the central passage 36, the intersecting passage 37, and the loop passage 38 are formed or defined in the case internal space, and the temperature-adjustment air unit 3 is laid out at a position at which the heat-exchanged air, merged together from the double air-flow systems, is sucked into the unit and the created temperature-adjusting air is blown off into the central passage 36.
By virtue of the specified layout/configuration, when controlling the internal temperature of battery pack BP by temperature-adjusting air (cold air, hot air), temperature-adjusting air can be circulated equally smoothly throughout the case internal space without any space having a lack in the quantity of temperature-adjusting air circulation.
Hence, it is possible to enhance the control accuracy and the control responsiveness in temperature-adjustment control of battery pack BP, thus suppressing an internal-temperature variation range of battery pack BP as narrow a range as possible. In other words, it is possible to maintain the internal temperature of battery pack BP in an appropriate temperature range that ensures an intended high battery performance.
[Harness-Connection Work Among Pack Components]
In the battery pack BP, the pack components mounted in the case internal space, are harness-connected each other, but it is necessary to simplify such a harness-connection work as much as possible. The harness-connection work among the pack components, reflecting the necessity discussed above, is hereunder explained. As shown in
First, the harness-connection work with the weak-electric harness 96 is explained. As shown in
The harness-connection work with the heavy-electric harness 97 is explained. As shown in
The harness-connection work with the weak-electric harness 98 is explained. As shown in
In this manner, all of the harness-connection works for weak-electric harness 96, heavy-electric harness 97, and weak-electric harness 98 are done by harness-wiring, harness-fixing, and connection between connectors. In particular, the harness-wiring of these works can be simplified. That is, regarding weak-electric harness 96, the short harness is only wired straight along the straight passage part 38a of loop passage 38. Regarding heavy-electric harness 97, the short harness is only wired straight along the intersecting passage 37. Regarding weak-electric harness 98, the harness is only wired into an H-shape in the plan view along the outer peripheral surfaces of battery modules 21, 22, and 23. That is, complicated harness-wiring that each of the harnesses has to be bent complicatedly along corners and grooves and the like is not required. Thus, it is possible to improve the harness durability as well as the harness-wiring workability, as compared to bent-harness routing along bent paths.
[Harness-Connection Work Between Junction Box and LB Controller]
In the harness-connection performed in the case internal space, it is necessary to simplify the harness-wiring work, and additionally to wire the harnesses such that the harnesses wired in the temperature-adjustment air passages do not act as a factor that disturbs the temperature-adjusting air flow. The harness-connection work between the junction box and the LB controller, reflecting the necessity discussed above, is hereunder explained.
The first embodiment adopts a specified configuration that junction box 5 and LB controller 6, which are arranged at respective positions spaced apart from each other and facing one straight passage part 38a of the temperature-adjustment air passages, are connected to each other via the weak-electric harness 96 wired along the one straight passage part 38a (see
Therefore, as discussed previously, in the harness-connection between junction box 5 and LB controller 6, it is possible to ensure smooth flow of temperature-adjusting air, while improving the harness-wiring workability and the harness durability.
The first embodiment adopts a configuration that the internal space of battery pack case 1 is partitioned into two regions in the fore-and-aft direction of the vehicle so as to define the battery module mounting region 7 and the electrical equipment mounting region 8, and junction box 5 is arranged in the electrical equipment mounting region 8 (see
For instance, assume that a comparative example adopts a configuration that a junction box is arranged in a battery module mounting region and located at a position of a clearance space defined between two opposed battery modules juxtaposed to each other in the vehicle width direction (i.e., at a position corresponding to the central passage 36 in the first embodiment). In the case of the comparative example, on the assumption that the width of a battery pack case is predetermined, regarding the mounting width of these two battery modules in the vehicle width direction, the occupation width occupied by the junction box must be subtracted, and thus the battery mounting space becomes narrow. In contrast, junction box 5 is arranged in the electrical equipment mounting region 8, separated from the battery module mounting region 7, and hence junction box 5 does not act as a factor that narrows the mounting width of battery module 2 in the vehicle width direction, thus ensuring an adequate battery mounting space.
For instance, assume that a comparative example adopts a configuration that a clearance space defined between two opposed battery modules juxtaposed to each other in the vehicle width direction is configured as a temperature-adjustment air passage. In the case of the comparative example, due to a junction box arranged in the temperature-adjustment air passage, the junction box acts to narrow a temperature-adjusting air flow passage cross-sectional area. In contrast, junction box 5 is arranged in the electrical equipment mounting region 8, separated from the battery module mounting region 7, in other words, junction box 5 is arranged outside of the temperature-adjustment air passages. Thus, junction box 5 does not act as a factor that narrows the temperature-adjusting air flow passage cross-sectional area. Hence, it is possible to ensure the flow rate of temperature-adjusting air flowing through the battery module mounting region 7.
In the first embodiment, battery module mounting region 7 is classified into a plurality of split rectangular regions 71, 72, and 73 configured to mount the plurality of battery modules 21, 22, and 23, respectively. The first embodiment adopts a layout/configuration that LB controller 6 is arranged upright in the first split rectangular region 71 of the plurality of split rectangular regions 71, 72, and 73, the first split rectangular region 71 being configured to mount the first battery module 21, constructed by battery cells upright-stacked in the vehicle width direction (see
For instance, as a comparative example, assume that a battery module mounting region is split into a plurality of split rectangular regions equipped with only a plurality of battery modules, and an LB controller is arranged in a certain region outside of the plurality of split rectangular regions. In the case of the comparative example, on the assumption that the split rectangular regions are configured and split to ensure temperature-adjustment air passages, the LB controller, arranged in the certain region outside of the split rectangular regions, acts as a factor that narrows the temperature-adjustment air passages. In contrast, LB controller 6 is arranged in the first split rectangular regions 71 in which the first battery module 21 is mounted, and thus the LB controller 6 does not act as a factor that narrows the temperature-adjusting air flow passage cross-sectional area. Hence, it is possible to ensure the flow rate of temperature-adjusting air flowing through the case internal space.
For instance, as a comparative example, assume that an LB controller is arranged in a plurality of split rectangular regions, but located in a flat-stacked state. In the case of the comparative example, the occupation area occupied by the flat-stacked LB controller widens, and the battery mounting space becomes narrow by just much that. In contrast, LB controller 6 is arranged and upright-stacked together with the battery cells, and thus the occupation area, occupied by the LB controller 6, can be suppressed narrowly. Hence, it is possible to ensure a maximum battery mounting space, while mounting the LB controller 6 in the battery module mounting region 7.
In the first embodiment, the temperature-adjustment air passages are configured to have the loop passage 38 for returning temperature-adjusting air, heat-exchanged with each of the plurality of battery modules 21, 22, and 23 and then flown into the circumference of the case internal space, to the temperature-adjustment air unit 3. The first embodiment adopts a configuration that straight passage part 38a is configured as a passage constructing a part of loop passage 38 and formed along one side of both sides of the battery pack case in the vehicle width direction (see
In the temperature-adjusting air case-internal-space circulation action as discussed above, the T-shaped passage, constructed by the central passage 36 and the intersecting passage 37, serves as a main passage for the temperature-adjusting air flow. When comparing the case where weak-electric harness 96 is wired in the central passage 36 or the intersecting passage 37 with the case where weak-electric harness 96 is wired in the loop passage 38, the former case where the weak-electric harness is wired in the central passage 36 or the intersecting passage 37 has a tendency for a drop of the case-internal-space circulation efficiency to be increased. In contrast, the passage, constructing a part of loop passage 38 and formed along one side of both sides of the battery pack case in the vehicle width direction, is configured as the straight passage part 38a along which weak-electric harness 96 is wired. Hence, it is possible to suppress a drop of the case-internal-space circulation efficiency to a minimum.
Effects are hereunder explained.
The battery pack structure for electric vehicles of the first embodiment can provide the following effects.
(1) In a battery pack structure for electric vehicles that a battery module 2 constructed by a battery cell assembly, a junction box 5 for performing supply, interception, and distribution of heavy-electric current by means of a relay circuit, and a battery controller (LB controller 6) for battery management are mounted in an internal space of a battery pack case 1, clearances, ensured when the battery module 2 is mounted in the internal space of the battery pack case 1, are configured as temperature-adjustment air passages through which temperature-adjusting air flows. The junction box 5 and the battery controller (LB controller 6) are arranged at positions spaced apart from each other and facing one straight passage part 38a of the temperature-adjustment air passages. Furthermore, a harness (weak-electric harness 96) via which the junction box 5 and the battery controller (LB controller 6) are connected to each other, is wired along the straight passage part 38a.
Therefore, when connecting the junction box 5 and the battery controller (LB controller 6) to each other via the harness, it is possible to ensure smooth flow of temperature-adjusting air, while improving both the harness-wiring workability and the harness durability.
(2) The internal space of the battery pack case 1 is partitioned into two regions in a fore-and-aft direction of the vehicle so as to define a battery module mounting region 7 and an electrical equipment mounting region 8, and the junction box 5 is arranged in the electrical equipment region 8.
Therefore, in addition to the effect (1), it is possible to ensure an adequate battery mounting space, since junction box 5 does not act as a factor that narrows the mounting width of battery module 2 in the vehicle width direction, and also to ensure the flow rate of temperature-adjusting air flowing through the battery module mounting region 7, since junction box 5 does not act as a factor that narrows the temperature-adjusting air flow passage cross-sectional area.
(3) The battery module mounting region 7 is classified into a plurality of split rectangular regions 71, 72, and 73 configured to mount a plurality of battery modules 21, 22, and 23, respectively, and the battery controller (LB controller 6) is arranged upright in a split rectangular region (a first split rectangular region 7) of the plurality of split rectangular regions 71, 72, and 73, the split rectangular region being configured to mount a battery module (a first battery module 21), constructed by battery cells upright-stacked in the vehicle width direction.
Therefore, in addition to the effect (2), it is possible to ensure the flow rate of temperature-adjusting air flowing through the case internal space, since the battery controller (LB controller 6) does not act as a factor that narrows the temperature-adjusting air flow passage cross-sectional area, and also to ensure a maximum battery mounting space, while mounting the battery controller (LB controller 6) in the battery module mounting region 7.
(4) The temperature-adjustment air passages are configured to have a loop passage 38 for returning temperature-adjusting air, heat-exchanged with each of the plurality of battery modules 21, 22, and 23 and then flown into a circumference of the case internal space, and the straight passage part 38a is configured as a passage constructing a part of the loop passage 38 and formed along one side of both sides of the battery pack case in the vehicle width direction.
Therefore, in addition to the effect (3), it is possible to suppress a drop of the case-internal-space circulation efficiency to a minimum, as compared to the case where the harness (weak-electric harness 96) is wired in the main passage into which temperature-adjusting air before heat-exchange flows.
While the foregoing is a description of the battery pack structure for electric vehicles in the first embodiment carried out the invention, it will be understood that the invention is not limited to the first embodiment shown and described herein, but that various changes and modifications may be made without departing from the scope or spirit of this invention as defined by the following claims.
In the first embodiment, as a battery module 2, three split battery modules 21, 22, and 23 are exemplified such that these battery modules are mounted in respective rectangular regions 71, 72, and 73 split each other, but a single module or two-split battery modules may be used as a battery module. In lieu thereof, four or more split battery modules may be used as a battery module. In the case of such multiple-splitting, a splitting technique is not limited to the first embodiment that adopts a splitting technique with a T-shaped passage. In lieu thereof, various splitting techniques may be utilized.
In the first embodiment, it is exemplified that the case internal space is partitioned into two regions in the fore-and-aft direction of the vehicle, one being a battery module mounting region 7 and the other being an electrical equipment mounting region 8, and junction box 5 is arranged in the electrical equipment mounting region 8. In lieu thereof, junction box 5 may be arranged at a position spaced apart from the LB controller, without partitioning the case internal space into a battery module mounting region and an electrical equipment mounting region.
In the first embodiment, it is exemplified that the battery controller (LB controller 6) is arranged upright in the first split rectangular region 71 of the plurality of split rectangular regions 71, 72, and 73, the first split rectangular region being configured to mount the first battery module 71, constructed by the battery cells upright-stacked in the vehicle width direction. In lieu thereof, the LB controller may be arranged at a position spaced apart from the junction box 5, without partitioning the case internal space into a battery module mounting region and an electrical equipment mounting region.
In the first embodiment, it is exemplified that the straight passage part 38a is configured as a passage constructing a part of the loop passage 38 for returning heat-exchanged temperature-adjusting air and formed along one side of both sides of the battery pack case in the vehicle width direction, but the straight passage part along which the harness is wired is not limited to such a passage part of the loop passage for returning heat-exchanged temperature-adjusting air. Any straight passage part constructing part of temperature-adjustment air passages, such as a straight passage extending in the vehicle width direction or in the fore-and-aft direction of the vehicle, may be used as the straight passage part.
In the first embodiment, it is exemplified that the battery pack structure of the invention is applied to one-box type electric vehicle employing only a drive motor as a drive source for running, but the battery pack structure for electric vehicles of the invention may be applied to various types of electric vehicles as well as a one-box type, such as a sedan type, a wagon type, an SUV type, and the like. Furthermore, it may be applied to a hybrid type of electric vehicle (a hybrid electric vehicle) employing both a drive motor and an engine as a drive source for running. That is, the battery pack structure of the invention may be applied to any type of electric vehicle employing a battery pack on which battery modules, a junction box, and a battery controller are mounted.
Tsujimura, Norihisa, Iwasa, Makoto, Takamatsu, Toshifumi, Tanigaki, Tatsunori
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Mar 21 2012 | Nissan Motor Co., Ltd. | (assignment on the face of the patent) | / | |||
Sep 18 2013 | TSUJIMURA, NORIHISA | NISSAN MOTOR CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 031635 | /0321 | |
Sep 18 2013 | IWASA, MAKOTO | NISSAN MOTOR CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 031635 | /0321 | |
Sep 18 2013 | TANIGAKI, TATSUNORI | NISSAN MOTOR CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 031635 | /0321 | |
Sep 20 2013 | TAKAMATSU, TOSHIFUMI | NISSAN MOTOR CO , LTD | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 031635 | /0321 |
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